Equalizer system

ABSTRACT

Equalizer system having at least two mutually interconnected and mutually interfering equalizers that exhibit different center frequencies, whose gains at the respective center frequencies are controllable by first external control signals, the first external control signals being supplied to an optimizer that therefrom generates first internal control signals for setting the gains of the equalizers at the respective center frequencies, the first internal control signals being modified relative to the first external control signals in such a way that the interferences arising between the equalizers are at least reduced.

This invention relates to an equalizer system for generating an output signal by equalizing an input signal, having at least two interconnected and mutually interfering equalizers that exhibit different center frequencies, whose gains at the respective center frequencies are controllable by first external control signals, the input signal being spectrally weighted in dependence on the external control signals.

Such equalizer systems, such as for example equalizer banks, are already on the market in various versions and are made up as a rule of a set of equalizers that are interconnected in a certain fashion with the use of a serial, parallel, or any other structure. The individual equalizers can be boost equalizers (presence equalizers) or cut equalizers (absence equalizers), that is, equalizers in which the gain is increased or respectively the gain is decreased at the respective center frequency.

The equalizers are characterized by their respective gain factors, center frequencies, and Q factors (bandwidths). Fashioned as corresponding filter units, the equalizers have finite bandwidths, so that connecting them together unavoidably leads to interferences between their frequency responses. As a result, the net amplitude response of the equalizer system can depart substantially from the gain factors set by the user (gain setting). The resulting gain factors can thus be much higher or much lower than the corresponding values of the gain setting, which has the consequence of unwanted coloration of the signal spectrum and an increase in the probability of overdriving.

Defects caused by interferences can be broken down into five categories: peaking, overdamping, gain reduction, damping reduction, and nonspecific (random) distortion of the frequency response.

Peaking occurs when the gains of a number of adjacent equalizers have the same arithmetic sign. In this case, the interference brings about a distinct boost or cut effect in dependence on the arithmetic sign of the gain. The frequency behavior of the equalizer bank then shows absolute gain values that are clearly higher than the user's settings. Under some circumstances this can go so far that the high gain values end in intolerable distortions of the frequency response (coloration) and/or in a rise in the probability of overdriving.

Such an effect is illustrated in FIG. 1. The gains of the five adjacent equalizers of the graphic equalizer bank shown by way of example are all set to +10 dB, while the gains of the other equalizers are set to 0 dB. FIG. 1 shows the gain characteristic of the individual equalizers as well as the net gain characteristic of the equalizer bank (heavier line), the peaking effect coming out clearly.

In the case where a cut equalizer and a boost equalizer are adjacent to each other, the interference of each equalizer effects a reduction in the absolute value of the gain of the other equalizer. As a consequence, the net gain characteristic versus frequency of an equalizer bank made up of two equalizers with opposing behavior is a reduction in the absolute value of the gain of both equalizers in comparison with the setting by the user.

This effect is illustrated in FIG. 2. What is depicted here is the gain characteristic of three adjacent equalizers, the outer two devices being boost equalizers with a positive gain of +10 dB while the middle device is a cut equalizer with a negative gain of −10 dB. Furthermore, FIG. 2 also shows the net gain characteristic (heavy line) of the equalizer bank versus frequency. It can be seen therefrom that the gain of the two boost equalizers is considerably diminished while the cut equalizer is almost entirely canceled by the damping interference effect caused by the two equalizers adjacent to it.

The case described in FIG. 3 is that in which the two effects cited above, that is, both peaking (as in FIG. 1) and a decrease in damping (as in FIG. 2), occur at the same time.

For the case where the gains of the individual equalizers are randomly distributed, a random combination of cut equalizers and boost equalizers also results. As a consequence, the resulting gain characteristic versus frequency is nonspecific, that is, random. FIG. 4 shows the gain characteristics of the individual equalizers in an example with a graphic equalizer bank exhibiting 10 octave bands whose individual gains are randomly set. The resulting net gain characteristic versus frequency (heavy line) here shows clearly the randomly distributed departures of the gain from the values set.

In order to oppose this, users up to now have attempted to vary the equalizer parameters manually in order to adapt the net frequency response to the desired setting, but this has been associated with substantial manual effort and doubtful success. In the professional field, certain settings have already been realized in advance and the corresponding parameters saved. The settings and thus the associated parameter sets were then recalled in later use and made the basis for setting. This way of proceeding, however, is severely limited by low flexibility and a lack of suitability for real-time use.

It is therefore an object of the invention to identify equalizer systems that not only offer high flexibility and suitability for real-time use in setting, but also require only slight manual effort.

This object is achieved with an equalizer system according to claim 1. Embodiments and developments of the inventive concept are the subject of the dependent claims.

It is consequently the idea of the invention to automate the variation and setting of the equalizer parameters for the realization of a setting desired by the user by an optimizer using for example a mathematical optimization procedure suitable for real-time use. Thus for example the parameters of the individual equalizers are systematically varied in accordance with a mathematical optimization strategy. The manual effort of setting is thus minimal because of the use of an automated setting procedure.

Upon each variation a certain optimization figure of merit (goal function, cost function) is formed and observed. The variation of parameters is continued in the direction in which the cost function decreases until the cost function has reached a certain predetermined minimum level. After each new setting of the equalizers by the user, the selected mathematical optimization can for example be performed with a corresponding computational routine and then the optimal parameter set can be passed on to an equalizer implementing routine by a setting routine. The amplitude response actually occurring can thus be determined directly, estimated, or simulated and then made the basis of the optimization.

This is achieved in particular by an equalizer system of the type stated at the outset in that the first external control signals are supplied to an optimizer that generates therefrom first internal control signals for setting the gains of the equalizers at the respective center frequencies, the first internal control signals being modified relative to the first external control signals in such a way that the interferences occurring between the equalizers are at least reduced. Here the first external control signals are a representation of the gain parameters desired by the user, while the first internal control signals represent the actual amplifier parameter sets used for setting the equalizers.

It can further be provided that second or respectively third provided external control signals are supplied to the optimizer for setting the center frequency and/or the Q factor of the equalizers. Not only graphic equalizer systems but also parametric equalizer systems can be implemented in this way.

Moreover, the optimizer can also generate second internal control signals for changing the center frequencies of the equalizers. These signals are needed in any case in conjunction with the second external control signals, but they can also be used without them in order to create an optimal frequency response of the equalizer system as a whole.

The optimizer can further generate third internal control signals for controlling the Q factor of the equalizers. Besides center frequency and gain, the Q factor is an alternative or additional parameter for attaining the frequency characteristic predetermined by the user.

The optimizer preferably employs an error-minimizing technique, in particular a nonlinear error-minimizing technique, the interferences that occur being taken as the errors. This error-minimizing technique preferably operates in iterative fashion. In this way a rapid approach to the optimal frequency characteristic specified by the user is achieved.

The invention will now be explained in greater detail based on exemplary embodiments depicted in the drawings, in which:

FIG. 1 shows the frequency characteristic of an equalizer bank with pronounced peaking,

FIG. 2 shows the frequency characteristic of an equalizer bank with a pronounced decrease in damping,

FIG. 3 shows the frequency characteristic of an equalizer bank with simultaneous peaking and damping reduction,

FIG. 4 shows the frequency characteristic of an equalizer bank with a random setting,

FIG. 5 shows a first embodiment of an equalizer system according to the invention as a graphic equalizer bank with serial structure,

FIG. 6 shows a second embodiment of an equalizer system according to the invention as a parametric equalizer bank with parallel structure,

FIG. 7 shows the optimized frequency characteristic for the equalizer bank of FIG. 1,

FIG. 8 shows the optimized frequency response of the equalizer bank of FIG. 2,

FIG. 9 shows the optimized frequency response of the equalizer bank of FIG. 3, and

FIG. 10 shows the optimized frequency response of the equalizer bank of FIG. 4.

In the exemplary embodiment of an equalizer system according to the invention depicted in FIG. 5, the starting point is a graphic equalizer bank 1 with fixed specified center frequencies and Q factors, which exhibit four individual equalizers 2 to 5. Equalizers 2 to 5 are connected in series and are fed from an input signal 6, which, correspondingly equalized, is already present as output signal 7 at the output of the last equalizer 5.

Further, there are controllers 8 to 11 with which a user specifies a desired frequency response by establishing the gains of individual equalizers 2 to 5 at their respective center frequencies. The settings specified by the user (gain setting) are not, however, supplied directly to equalizers 2 to 5 as usual but are first conveyed on to an optimizer 12, which then generates first internal control signals 13 to 16 from first external control signals 17 to 20 furnished by controllers 8 to 11. On the basis of internal control signals 13 to 16, the gain factors at the center frequencies of equalizers 2 to 5 are then set as specified by optimizer 12.

In development of the invention, the Q factor of equalizers 2 to 5 is also additionally changed by optimizer 12 in dependence on the settings actuated at controllers 8 to 11. This is effected by internal control signals 21 to 24. The actual amplitude response of filter bank 1 can thus be still more precisely adapted to the setting specified by the user.

Optimizer 12 employs a mathematical optimization procedure suitable for real-time use, in which the parameters of the individual equalizers are systematically varied in iterative fashion in accordance with a specified optimization strategy until the optimal setting has been found. A certain optimization figure of merit (goal function, cost function) is formed and evaluated after each parameter variation. The variation of parameters is continued in the direction in which the cost function decreases until the cost function has reached a certain predetermined minimum level.

Optimization is effected for example with a nonlinear optimization procedure that is executed in a processing unit 25. The selected mathematical optimization process is executed after each new setting of equalizer system 1 by the user and the optimal parameter set is passed to an equalizer implementation routine by a setting routine executed in a processing unit 26, processing units 25 and 26 possibly being one and the same. The implementation routine can for example be executed in a further processing unit 27 (or also, however, in processing units 25 or 26).

Another embodiment of an equalizer system according to the invention is illustrated in FIG. 6, a parametric equalizer bank being depicted here. Equalizer bank 27 comprises three individual equalizers 28, 29, and 30, which are interconnected in a parallel structure by an adder 31. To this end, an input signal 32 is applied to all three equalizers 28, 29, 30 at the same time, the outputs of the three equalizers being led to adder 31. Output signal 33 caused by equalization from input signal 32 can then be picked off at the output of adder 31.

The amplitude response of equalizer system 58 desired by the user is set by the user with six controllers 34 to 39. The six controllers are broken down into three groups, one group being assigned to each of equalizers 28, 29, 30. Within each group there is one controller 34, 36, 38 for setting the respective center frequencies, the other controller 35, 37, 39 in each group serving for setting the gain at this center frequency. Controllers 34 to 39 generate first external control signals 41, 43, 45 for controlling the gain and second external control signals 40, 42, 44 for controlling the center frequencies. These signals are supplied to an optimizer 46, which, in correspondence to optimizer 12 in FIG. 5, likewise exhibits a first and a second processor 47, 48. In addition, there is a processor 59 for performing an implementation routine and thus for setting equalizers 28, 29, 30. Optimization routines and setting routines are handled in turn with processors 47 and 48.

Further, there can also be third external control signals for setting the Q factor by the user, which third external control signals are likewise supplied to optimizer 46 and consequently become the basis for optimization. For greater clarity, however, these are not depicted in the case of the present exemplary embodiment.

Optimizer 46 generates at least first 49, 52, 55 and second 50, 53, 56 internal control signals for setting the center frequency and gain of equalizers 28, 29, 30 as well as, furthermore, in development of the invention (if necessary), also third internal control signals 51, 54, 57 for controlling the Q factor.

In what follows, the mode of operation of optimizers 12 and 27 is now illustrated in general as a procedure for solving a nonlinear optimization problem in general and as a nonlinear curve fitting in particular. In the context of curve fitting, the gains specified by the user can be interpreted as sample values of a desired amplitude response that is to be approximated by a so-called model function.

Consider first an equalizer bank made up of a certain number of equalizers connected in series, for example according to FIG. 5. It is assumed that the gains (in dB) of the individual equalizers at their respective center frequencies are fixed and specified. Further, certain desired gains of the equalizer bank at several significant intermediate frequencies are assumed, specifically one between every two adjacent center frequencies.

The gains at the center frequencies and those at the frequencies lying therebetween are taken as the data set for curve fitting. The sum of the logarithms of the formally expressed amplitude responses (in dB) of the individual equalizers, with gain, Q factor and center frequency, still unknown parameters, is taken as the curve-fitting function (model function).

The next step is the selection of a optimization procedure (curve-fitting procedure or minimization procedure) suitable for the problem at hand. For example, numerous iterative optimization techniques such as for example Newton methods, gradient methods, and coordinate exchange methods are described in D. A. Pierre, Optimization Theory with Applications, John Wiley and Sons, New York 1969. In the present case, with an view to real-time implementation, a coordinate exchange method is chosen because it is of relatively slight complexity. In the same way, however, alternative optimization procedures can be employed.

Next a measure (norm) for the quality of curve fitting is needed. An example of such a measure is the Euclidean norm, that is, the square root of the sum of the squares, i.e., the square root of the sum of the squares of all the deviations of the model function from the data points and thus the square root of the sum of all squared errors. Further, a condition for terminating the iteration and finally suitable initial values for the unknown parameters are defined. Only after this has been done is the curve-fitting procedure begun, and it is run in an iterative loop until the condition for terminating the iteration is encountered.

The N user-defined gains (in dB) G_(i), I=1, 2, . . . , N, at the corresponding center frequencies F_(ci), I=1, 2, . . . , N, and additionally N-1 suitably predicted and desired gains (in dB) G_(mi), I=1, 2, . . . , N−1, each at a favorably selected intermediate frequency F_(mi), I=1, 2, . . . , N, are defined as the set of data points to be subjected to curve fitting.

The resulting 2N−1 data points can be assumed as elements of a data point vector: {overscore (y)} ^(T)=({tilde over (G)} ₁ , {tilde over (G)} ₂ , . . . {tilde over (G)} _(2N−1)), {tilde over (G)} _(2i−1) =G _(i) ,i=1,2, . . . , N;{tilde over (G)} _(2i) =G _(mi) ,i=1,2, . . . , N−1 where the vector for the associated frequency points is {overscore (x)} ^(T)=({tilde over (F)} ₁ ,{tilde over (F)} ₂ , . . . {tilde over (F)} _(2N−1)), {tilde over (F)} _(2i−1) =F _(ci) ,i=1,2, . . . , N;{tilde over (F)} _(2i) =F _(mi) , i=1,2, . . . , N−1

The data point vector is also used in determining the measure of quality for curve fitting at each iteration step, by calculating the Euclidean distance of this vector from the corresponding vector of the values given by the model function described in what follows.

In order to form the model function, consider an equalizer bank with N equalizers connected in series (conventional analog devices for simplicity in the presentation) with the unknown parametric center frequencies F_(ci), gains G_(i) (in dB) with G_(i)=20 log A_(i), and Q factors Q_(i), i=1, 2, . . . , N. Each individual equalizer has the frequency-domain transfer function ${{H_{i}(f)} = \frac{1 - \left( {f/{Fc}_{i}} \right)^{2} + {{j\left( {A_{i}/Q_{i}} \right)}\left( {f/{Fc}_{i}} \right)}}{1 - \left( {f/{Fc}_{i}} \right)^{2} + {{j\left( {1/Q_{i}} \right)}\left( {f/{Fc}_{i}} \right)}}},\quad{i = 1},2,\ldots\quad,N$ and hence the logarithmic amplitude response function (in dB) Me _(i)(f)=10 log {[1−(f/Fc _(i))²]²+(A ² ^(i) /Q ² _(i))(f/Fc _(i))²} −10 log {[1−(f/Fc _(i))²]²+(1/Q ² _(i))(f/Fc _(i))²}

The model function M({overscore (p)}, f) for our curve fitting problem is based on the net amplitude response (in dB) of the equalizer bank (made up of N individual equalizers): ${M\left( {\overset{\_}{p},f} \right)} = {\sum\limits_{i = 1}^{N}{{Me}_{i}\left( {{Fc}_{i},G_{i},Q_{i},f} \right)}}$ where the unknown parameter vector is {overscore (p)} ^(T)=(Fc ₁ ,G ₁ ,Q ₁ , . . . Fc _(N) ,G _(N) ,Q _(N))

With this function the curve fitting is now performed as described above on the basis of the set of data points (data point vector).

The well-known sum of squares measure ${D\left( \overset{\_}{p} \right)} = {\sum\limits_{i = 1}^{{2\quad N} - 1}\left\lbrack {{M\left( {\overset{\_}{p},{f = {\overset{\sim}{F}}_{i}}} \right)} - {\overset{\sim}{G}}_{i}} \right\rbrack^{2}}$ is employed as the measure of the quality of curve fitting in each iteration step.

In connection with optimizations, this measure is also frequently referred to as a cost function. In the theory of mathematical optimizations it is often characterized as the measure based on the so-called L2 norm. Alternative norms such as for example the minimax norm can also be employed.

With regard to a vector-space description of the present problem, the variable parameters can be taken as independent coordinates of a vector space. Each arbitrary parameter vector points to a point in this space. Every point in this space is then transformed to some positive number, namely the Euclidean distance (the curve fitting measure), by the model function in conjunction with the cost function. A point in the parameter space is sought that exhibits the shortest Euclidean distance in the simplified sense.

The interference compensation problem to be solved can here be viewed as a nonlinear minimization problem according to the least-squares method. Nonlinear because the model function, similarly to the cost function, depends on the parameters in a nonlinear way. Thus what is sought is the optimal parameter vector p₀ that minimizes the cost function D(p): MinimizeD({overscore (p)})l with some {overscore (p)} _(o)=(Fc _(1o) ,G _(1o) ,Q _(1o) , . . . , Fc _(No) ,G _(No) ,Q _(No))

In most cases nonlinear minimization problems are solved through the use of a numerical iterative procedure. An important fundamental problem in all nonlinear optimization procedures is the fact that the cost function may exhibit not a unique global minimum but various local minima. This must also be taken into account for the present applications.

As has been mentioned, it is important to find a, or the unique, optimal parameter vector that minimizes the cost function. In order to reach this goal, a suitable fast-searching minimization strategy must first be established, the condition for termination of the iteration must be defined, and suitable initial values of the parameters must be set for the first iteration round.

Numerous minimization procedures are described in the prior art; these can essentially be broken down into three categories: Newton methods, gradient methods, and coordinate exchange methods.

Coordinate exchange procedures are slow but have the advantage of relatively slight complexity. This procedure will therefore be employed for the analysis that follows.

The procedure can be briefly outlined as follows. In each iteration step, the parameters, one after another, are incremented and then decremented by a certain amount. After each parameter is changed, the model function is calculated and from this, the cost function with the use of the temporarily changed parameter. Next, a test is performed to determine whether the parameter changes increase or decrease the cost function. If the cost function is diminished, the current parameter is set according to the positive or negative amount; otherwise it is left unchanged. In the same way, the next parameter is now changed and the dependent cost function determined.

After all parameters have been run through in this manner, the iteration loop is repeated with the use of the new parameter vector, and this is done over and over until the condition for the termination of the iterations is satisfied. The iterative procedure is terminated when this is the case.

Before the iterative procedure is begun, however, suitable initial values of the unknown parameters must be set for the first iteration. In nonlinear optimization procedures in general, this operation is a relatively problematic step because a poorly chosen initial parameter set ends, in the worst case, in the algorithm diverging. The initial values must therefore be selected with great care in order to make the iterative process converge as rapidly as possible to (at least) a (local) minimum.

The equalizer system according to the invention can be used with an arbitrary system structure in conjunction with both graphical as well as parametric equalizer banks. For simplicity, the explanation in the case of the exemplary embodiments depicted in FIGS. 7 to 10 proceeds from a graphic equalizer bank with 10 octave bands. In this case the gains and Q factors of the individual equalizers are taken as the variable parameter vector of the model function. The center frequencies should be fixed for the analysis that follows; that is, they are not used as elements of the change of parameters. What is more, the user's corresponding settings are taken as the basis for the initial values of the parameters in the present case.

The gains and the Q factors of the individual equalizers are then employed as elements of the parameter vector; these values form the system of coordinates for the space over which the minimum of the cost function is sought. The coordinate exchange procedure that is to be employed here operates in the following way:

As already mentioned, various types of parameters are available, namely the gains and the Q factors, both of which can be varied in order to reach the optimum. First, for example, the optimization procedure is carried out with variations of the gains only, then the procedure is repeated with the Q factors. A condition for the termination of iteration is established at the beginning of the gain and Q factor optimization.

Each iteration step begins with for example an increase, followed by a decrease, of the gains (or respectively the Q factors), and specifically of one gain (or respectively Q factor) after another, by a certain amount. In this way the parameter vector is thus varied one element after another, and the net frequency response is calculated or estimated upon each variation of an element, whence the cost function is calculated and tested against a condition for the termination of iteration. The iteration loop is stopped as soon as the termination condition is satisfied; this means that the optimal point has been reached. Otherwise, the loop is continued.

The differences in the amplitude response with and without optimization are compared in FIGS. 1 and 7. The user's setting is taken as basis for the initial parameter set there, from which FIG. 1 also commences. In order to reduce the pronounced peakings, only the gains were varied here (iteratively, as described above). The result can be seen in FIG. 5, with dotted lines depicting intermediate results and solid lines the final result. The step size for the gain was 1 dB here, and satisfactory results were obtained after just four iteration rounds.

Proceeding from the exemplary embodiment of FIG. 2, an attempt is made, as shown in FIG. 8, to compensate for the interference effects by varying only the Q factors. Here the Q factors were varied in the range between 1.4 and 2.6 or respectively between 0.8 and 1.4. As can be seen, the user's gain settings are reached here essentially without deviation.

In the more complex exemplary embodiment of FIG. 3, both gain variations and also variations of the Q factor are employed for its optimization. The gain steps were set at 0.5 dB. The optimization procedure converges to a net amplitude response (not shown) that, as expected, departs far from the user's actual gain setting at some points. The corresponding cost function, also not shown, moves to a minimal value that cannot be further diminished by further iteration loops. Thus a curve fit (interference compensation) cannot be satisfactorily achieved with gain variation alone.

The results of the net amplitude response are depicted in FIG. 9 (dotted line representing intermediate results, solid line representing final results), a Q factor variation being employed in the optimization procedure along with a gain variation. In the present example, an acceptable net amplitude response is obtained after three gain iterations and eight Q factor iterations.

Finally, the optimization procedure was applied with combined gain and Q factor variation for the setting shown in FIG. 4. The resulting net amplitude response is depicted in FIG. 8 (solid line) in comparison with the initial, unoptimized net amplitude response (dashed line) from FIG. 4. For the sake of greater clarity, the intermediate results are not depicted here.

Thus it has been shown that the optimizer sets an actual transfer behavior that essentially corresponds to that set by the user. The invention is not, however, limited only to iterative systems but can also be implemented by neural networks or through fuzzy logic.

List of Reference Characters

-   1 Equalizer bank -   2 Equalizer -   3 Equalizer -   4 Equalizer -   5 Equalizer -   6 Input signal -   7 Output signal -   8 Controller -   9 Controller -   10 Controller -   11 Controller -   12 Optimizer -   13 Control signal -   14 Control signal -   15 Control signal -   16 Control signal -   17 Control signal -   18 Control signal -   19 Control signal -   20 Control signal -   21 Control signal -   22 Control signal -   23 Control signal -   24 Control signal -   25 Processing unit -   26 Processing unit -   27 Processing unit -   28 Equalizer -   29 Equalizer -   30 Equalizer -   31 Adder -   32 Input signal -   33 Output signal -   34 Controller -   35 Controller -   36 Controller -   37 Controller -   38 Controller -   39 Controller -   40 Control signal -   41 Control signal -   42 Control signal -   43 Control signal -   44 Control signal -   45 Control signal -   46 Optimizer -   47 Processor -   48 Processor -   49 Control signal -   50 Control signal -   51 Control signal -   52 Control signal -   53 Control signal -   54 Control signal -   55 Control signal -   56 Control signal -   57 Control signal -   58 Equalizer bank -   59 Processing unit 

1. Equalizer system for generating an output signal by equalizing an input signal (6, 32), comprising: at least two interconnected and mutually interfering equalizers that exhibit different center frequencies, whose gains at the respective center frequencies are controllable by first external control signals, the input signal being spectrally weighted in dependence on the external control signals, wherein the first external control signals are supplied to an optimizer that generates therefrom first internal control signals for setting the gains of the equalizers at the respective center frequencies, the first internal control signals being modified relative to the first external control signals in such a way that the interferences occurring between the equalizers are reduced.
 2. The equalizer system of claim 1, wherein the second external control signals are supplied to the optimizer for controlling the center frequency of the equalizers.
 3. The equalizer of claim 1 wherein the optimizer generates second internal control signals for altering the center frequency of the equalizers.
 4. The equalizer of claim 3, wherein the optimizer generates third internal control signals for controlling the Q factor of the equalizers.
 5. The equalizer system of claim 4, wherein the optimizer executes an error-minimizing procedure, the interferences that occur being taken as the errors.
 6. The equalizer system of claim 5, wherein the error-minimizing procedure executed by the optimizer comprises a nonlinear error-minimizing procedure.
 7. The equalizer system of claim 6, wherein the error-minimizing procedure executed by the optimizer operates in iterative fashion.
 8. The equalizer system of claim 2, wherein third external control signals are provided for setting the Q factor of the equalizers by the user. 